From Centralized to Decentralized Model of Simulation-Based Education: Curricular Integration of Take-Home Simulators in Nursing Education

Improving Hands-On Suture Opportunities for Medical Students: A Collaborative Initiative Between Medical Students and a Simulation Lab

Technical skills are an integral part of the practice of medicine. Simulation-based education (SBE) is a widely employed approach that allows students to acquire these skills prior to practicing them in the clinical setting. To discuss the state of SBE and potential avenues to improving education and medical student experiences, this editorial will explore the lived experiences of junior medical students, the observations of a research graduate student's informal conversations, and an educational quality improvement (EQI) pilot conducted by students at a satellite medical campus. Pre-clerkship Canadian medical students reported having limited opportunities to practice their technical skills. For some, these SBE sessions came at inopportune times in their academic journey, preventing them from maximizing their chances at real-world exposure. Having identified this as an issue, students sought ways to allow themselves and their peers to practice technical skills outside of the undergraduate medical curriculum, such as organizing peer and near-peer-led suturing events. Still, students feel these sessions are a start but do not adequately meet their needs, as access to practice materials is still restricted to the sparse events held by students, and experienced feedback is scant. To address these needs, we explore how simulation technology research and development labs can support peer-assisted learning by training students to teach technical skills and provide feedback to their peers. We also propose increasing access to simulation materials asynchronously to allow for practice when the students can benefit most.

Adapting the Gamified Educational Networking Online Learning Management System to Test a Decentralized Simulation-Based Education Model to Instruct Paramedics-in-Training on the Emergency Intraosseous Access and Infusion Skill

Intraosseous (IO) access and infusion is a safe and rapid alternative to intravenous access in obtaining vascular access for administering fluids and drugs. Healthcare professionals, such as primary and advanced care paramedics, use IO access and infusion in emergency circumstances where peripheral intravenous routes are inaccessible. IO access skills require hands-on training, which can be done remotely if the participants have access to simulation, instructions, guidance, and feedback. For the purpose of moving the training outside of the simulation laboratories, we have developed (1) an inexpensive and scalable three-dimensional (3D) printed and silicone-based advanced adult proximal tibial IO access and infusion simulator and (2) a unique learning management system (LMS) for remote simulation-based training. The LMS was built using the Django platform and supports experiential learning by providing access to educational and instructional content (including virtual simulation and serious games), allowing peers to communicate among themselves and with subject-matter experts, provide and receive feedback asynchronously, and engage in learning using gamification elements. The aim of this technical report is to describe the process of development and the final product of the LMS as a research and educational tool to scaffold remote learning of emergency IO skills by paramedics-in-training.

Comparing Learning Outcomes in Cardiopulmonary Resuscitation (CPR) and/or Automated External Defibrillator (AED) Training for Laypeople in Face-to-Face, Online, and Mixed Training Methods: An Integrative Literature Review

Cardiovascular diseases and cardiac arrest (CA) are the main causes of death worldwide. This review aims to identify publications on the learning outcomes for the use of an automated external defibrillator (AED) and/or cardiopulmonary resuscitation (CPR) to train laypeople (LP), the method of training used, the year of publication and their recommendations. We employed Miller's assessment pyramid to describe learning outcomes as knowledge, skills, and confidence. The methods of training are face-to-face, online, and mixed. The evidence found in this study will be used to support the development and validation of a simulation-based training program to teach LP to operate AEDs delivered by drones in rural and remote (R&R) locations. This article is an integrative literature review with a quantitative and qualitative research design and is composed of seven steps: research question, inclusion and exclusion criteria, search and selection of studies, the role of a second reviewer of the findings, data analysis, interpretation and discussion of the results, and finally knowledge synthesis. The results of this review demonstrate that there are no significant differences in the learning outcomes of the different training methods. Since these findings suggest good results in all methods, the development of a training program based on face-to-face, online, and mixed, especially for places with few resources such as R&R places, indicates all methods can be used as good practices to develop training programs.

Development and Initial Assessment of a Novel and Customized Bile Duct Simulator for Handsewn Anastomosis Training

Simulation-based medical education allows for the training and maintenance of healthcare skills in a safe and controlled environment. In this technical report, the development and initial evaluation of a bile duct anastomosis simulator are described. The simulator was developed using additive manufacturing techniques such as three-dimensional (3D) printing and silicone work. The final product was produced by maxSIMhealth, a research lab at Ontario Tech University (Oshawa, ON, Canada), and included four individual silicone bile ducts, based on the expert opinions from surgeons at the Centre Hospitalier de l'Université de Montréal (Montreal, QC, Canada), and a 3D-printed maxSIMclamp, which was described in a previous report. The evaluation was conducted by nine individuals consisting of surgeons, surgical residents, and medical students to assess the fidelity, functionality, and teaching quality of the simulator. The results from the evaluation indicate that the simulator needs to improve its fidelity by being softer, thinner, and beige. On the other hand, the results also indicate that this simulator is extremely durable and can be used as a training tool for surgical residents with some minor improvements.

Hacking Intraosseous Infusion Skills Training With 3D Printing: maxSIMIO Drilling System

Intraosseous (IO) infusion is an alternative way to access the vascular system to administer drugs and fluids, which is particularly helpful when the commonly used peripheral intravenous route is inaccessible. The IO procedure can be done using a drill that involves disinfecting the area, landmarking the insertion point, seating the needle in a firm and stable position in the bone, and then delivering a smooth fluid flush. However, in the current medical training landscape, access to commercially available IO drills such as the Arrow® EZ-IO® Power Driver (EZ-IO; Teleflex, Morrisville, North Carolina, United States) is difficult, especially for rural and remote areas, due to the high costs. Furthermore, the EZ-IO is not rechargeable and does not clearly indicate the remaining battery life, which could potentially put patients at risk during the IO procedure. This technical report aims to address these concerns by describing the development of an alternative, affordable, and reliable IO drilling system for training use: the maxSIMIO Drilling System. This system consists of a cordless and rechargeable IKEA screwdriver which connects to a conventional, hexagon-shaped 3D-printed drill bit needle adapter. Two needle adapters were created: Version A was designed to use a friction-based mechanism to couple the screwdriver with the EZ-IO training needle, while Version B relies on a magnetic mechanism. The major differences between the EZ-IO and the screwdriver are that a) the EZ-IO has only one rotation to advance the cannula while the screwdriver features both directions, b) the EZ-IO is not rechargeable while the screwdriver is, and c) the EZ-IO has a custom needle holder that can fit any EZ-IO training needle size while the screwdriver needs to have a custom needle adapter made to connect to the EZ-IO training needle. Overall, through this exploration, the features of the maxSIMIO Drilling System in comparison to the EZ-IO appear more accessible for IO training. Future considerations for this development include gathering clinical expertise through rigorous testing of this novel system.